/***
 * ASM: a very small and fast Java bytecode manipulation framework
 * Copyright (c) 2000-2011 INRIA, France Telecom
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 3. Neither the name of the copyright holders nor the names of its
 *    contributors may be used to endorse or promote products derived from
 *    this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
 * THE POSSIBILITY OF SUCH DAMAGE.
 */
package com.sinosoft.monitor.org.objectweb.asm.commons;

import java.util.AbstractMap;
import java.util.ArrayList;
import java.util.BitSet;
import java.util.HashMap;
import java.util.Iterator;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Set;

import com.sinosoft.monitor.org.objectweb.asm.Label;
import com.sinosoft.monitor.org.objectweb.asm.MethodVisitor;
import com.sinosoft.monitor.org.objectweb.asm.Opcodes;
import com.sinosoft.monitor.org.objectweb.asm.Type;
import com.sinosoft.monitor.org.objectweb.asm.tree.AbstractInsnNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.InsnList;
import com.sinosoft.monitor.org.objectweb.asm.tree.InsnNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.JumpInsnNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.LabelNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.LocalVariableNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.LookupSwitchInsnNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.MethodNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.TableSwitchInsnNode;
import com.sinosoft.monitor.org.objectweb.asm.tree.TryCatchBlockNode;

/**
 * A {@link com.sinosoft.monitor.org.objectweb.asm.MethodVisitor} that removes JSR instructions and
 * inlines the referenced subroutines.
 * <p/>
 * <b>Explanation of how it works</b> TODO
 *
 * @author Niko Matsakis
 */
public class JSRInlinerAdapter extends MethodNode implements Opcodes {

	private static final boolean LOGGING = false;

	/**
	 * For each label that is jumped to by a JSR, we create a BitSet instance.
	 */
	private final Map<LabelNode, BitSet> subroutineHeads = new HashMap<LabelNode, BitSet>();

	/**
	 * This subroutine instance denotes the line of execution that is not
	 * contained within any subroutine; i.e., the "subroutine" that is executing
	 * when a method first begins.
	 */
	private final BitSet mainSubroutine = new BitSet();

	/**
	 * This BitSet contains the index of every instruction that belongs to more
	 * than one subroutine. This should not happen often.
	 */
	final BitSet dualCitizens = new BitSet();

	/**
	 * Creates a new JSRInliner. <i>Subclasses must not use this
	 * constructor</i>. Instead, they must use the
	 * {@link #JSRInlinerAdapter(int, MethodVisitor, int, String, String, String, String[])}
	 * version.
	 *
	 * @param mv         the <code>MethodVisitor</code> to send the resulting inlined
	 *                   method code to (use <code>null</code> for none).
	 * @param access     the method's access flags (see {@link Opcodes}). This
	 *                   parameter also indicates if the method is synthetic and/or
	 *                   deprecated.
	 * @param name       the method's name.
	 * @param desc       the method's descriptor (see {@link Type}).
	 * @param signature  the method's signature. May be <tt>null</tt>.
	 * @param exceptions the internal names of the method's exception classes (see
	 *                   {@link Type#getInternalName() getInternalName}). May be
	 *                   <tt>null</tt>.
	 */
	public JSRInlinerAdapter(final MethodVisitor mv, final int access,
	                         final String name, final String desc, final String signature,
	                         final String[] exceptions) {
		this(Opcodes.ASM4, mv, access, name, desc, signature, exceptions);
	}

	/**
	 * Creates a new JSRInliner.
	 *
	 * @param api        the ASM API version implemented by this visitor. Must be one
	 *                   of {@link Opcodes#ASM4}.
	 * @param mv         the <code>MethodVisitor</code> to send the resulting inlined
	 *                   method code to (use <code>null</code> for none).
	 * @param access     the method's access flags (see {@link Opcodes}). This
	 *                   parameter also indicates if the method is synthetic and/or
	 *                   deprecated.
	 * @param name       the method's name.
	 * @param desc       the method's descriptor (see {@link Type}).
	 * @param signature  the method's signature. May be <tt>null</tt>.
	 * @param exceptions the internal names of the method's exception classes (see
	 *                   {@link Type#getInternalName() getInternalName}). May be
	 *                   <tt>null</tt>.
	 */
	protected JSRInlinerAdapter(final int api, final MethodVisitor mv,
	                            final int access, final String name, final String desc,
	                            final String signature, final String[] exceptions) {
		super(api, access, name, desc, signature, exceptions);
		this.mv = mv;
	}

	/**
	 * Detects a JSR instruction and sets a flag to indicate we will need to do
	 * inlining.
	 */
	@Override
	public void visitJumpInsn(final int opcode, final Label lbl) {
		super.visitJumpInsn(opcode, lbl);
		LabelNode ln = ((JumpInsnNode) instructions.getLast()).label;
		if (opcode == JSR && !subroutineHeads.containsKey(ln)) {
			subroutineHeads.put(ln, new BitSet());
		}
	}

	/**
	 * If any JSRs were seen, triggers the inlining process. Otherwise, forwards
	 * the byte codes untouched.
	 */
	@Override
	public void visitEnd() {
		if (!subroutineHeads.isEmpty()) {
			markSubroutines();
			if (LOGGING) {
				log(mainSubroutine.toString());
				Iterator<BitSet> it = subroutineHeads.values().iterator();
				while (it.hasNext()) {
					BitSet sub = it.next();
					log(sub.toString());
				}
			}
			emitCode();
		}

		// Forward the translate opcodes on if appropriate:
		if (mv != null) {
			accept(mv);
		}
	}

	/**
	 * Walks the method and determines which internal subroutine(s), if any,
	 * each instruction is a method of.
	 */
	private void markSubroutines() {
		BitSet anyvisited = new BitSet();

		// First walk the main subroutine and find all those instructions which
		// can be reached without invoking any JSR at all
		markSubroutineWalk(mainSubroutine, 0, anyvisited);

		// Go through the head of each subroutine and find any nodes reachable
		// to that subroutine without following any JSR links.
		for (Iterator<Map.Entry<LabelNode, BitSet>> it = subroutineHeads
				.entrySet().iterator(); it.hasNext(); ) {
			Map.Entry<LabelNode, BitSet> entry = it.next();
			LabelNode lab = entry.getKey();
			BitSet sub = entry.getValue();
			int index = instructions.indexOf(lab);
			markSubroutineWalk(sub, index, anyvisited);
		}
	}

	/**
	 * Performs a depth first search walking the normal byte code path starting
	 * at <code>index</code>, and adding each instruction encountered into the
	 * subroutine <code>sub</code>. After this walk is complete, iterates over
	 * the exception handlers to ensure that we also include those byte codes
	 * which are reachable through an exception that may be thrown during the
	 * execution of the subroutine. Invoked from <code>markSubroutines()</code>.
	 *
	 * @param sub        the subroutine whose instructions must be computed.
	 * @param index      an instruction of this subroutine.
	 * @param anyvisited indexes of the already visited instructions, i.e. marked as
	 *                   part of this subroutine or any previously computed subroutine.
	 */
	private void markSubroutineWalk(final BitSet sub, final int index,
	                                final BitSet anyvisited) {
		if (LOGGING) {
			log("markSubroutineWalk: sub=" + sub + " index=" + index);
		}

		// First find those instructions reachable via normal execution
		markSubroutineWalkDFS(sub, index, anyvisited);

		// Now, make sure we also include any applicable exception handlers
		boolean loop = true;
		while (loop) {
			loop = false;
			for (Iterator<TryCatchBlockNode> it = tryCatchBlocks.iterator(); it
					.hasNext(); ) {
				TryCatchBlockNode trycatch = it.next();

				if (LOGGING) {
					// TODO use of default toString().
					log("Scanning try/catch " + trycatch);
				}

				// If the handler has already been processed, skip it.
				int handlerindex = instructions.indexOf(trycatch.handler);
				if (sub.get(handlerindex)) {
					continue;
				}

				int startindex = instructions.indexOf(trycatch.start);
				int endindex = instructions.indexOf(trycatch.end);
				int nextbit = sub.nextSetBit(startindex);
				if (nextbit != -1 && nextbit < endindex) {
					if (LOGGING) {
						log("Adding exception handler: " + startindex + '-'
								+ endindex + " due to " + nextbit + " handler "
								+ handlerindex);
					}
					markSubroutineWalkDFS(sub, handlerindex, anyvisited);
					loop = true;
				}
			}
		}
	}

	/**
	 * Performs a simple DFS of the instructions, assigning each to the
	 * subroutine <code>sub</code>. Starts from <code>index</code>. Invoked only
	 * by <code>markSubroutineWalk()</code>.
	 *
	 * @param sub        the subroutine whose instructions must be computed.
	 * @param index      an instruction of this subroutine.
	 * @param anyvisited indexes of the already visited instructions, i.e. marked as
	 *                   part of this subroutine or any previously computed subroutine.
	 */
	private void markSubroutineWalkDFS(final BitSet sub, int index,
	                                   final BitSet anyvisited) {
		while (true) {
			AbstractInsnNode node = instructions.get(index);

			// don't visit a node twice
			if (sub.get(index)) {
				return;
			}
			sub.set(index);

			// check for those nodes already visited by another subroutine
			if (anyvisited.get(index)) {
				dualCitizens.set(index);
				if (LOGGING) {
					log("Instruction #" + index + " is dual citizen.");
				}
			}
			anyvisited.set(index);

			if (node.getType() == AbstractInsnNode.JUMP_INSN
					&& node.getOpcode() != JSR) {
				// we do not follow recursively called subroutines here; but any
				// other sort of branch we do follow
				JumpInsnNode jnode = (JumpInsnNode) node;
				int destidx = instructions.indexOf(jnode.label);
				markSubroutineWalkDFS(sub, destidx, anyvisited);
			}
			if (node.getType() == AbstractInsnNode.TABLESWITCH_INSN) {
				TableSwitchInsnNode tsnode = (TableSwitchInsnNode) node;
				int destidx = instructions.indexOf(tsnode.dflt);
				markSubroutineWalkDFS(sub, destidx, anyvisited);
				for (int i = tsnode.labels.size() - 1; i >= 0; --i) {
					LabelNode l = tsnode.labels.get(i);
					destidx = instructions.indexOf(l);
					markSubroutineWalkDFS(sub, destidx, anyvisited);
				}
			}
			if (node.getType() == AbstractInsnNode.LOOKUPSWITCH_INSN) {
				LookupSwitchInsnNode lsnode = (LookupSwitchInsnNode) node;
				int destidx = instructions.indexOf(lsnode.dflt);
				markSubroutineWalkDFS(sub, destidx, anyvisited);
				for (int i = lsnode.labels.size() - 1; i >= 0; --i) {
					LabelNode l = lsnode.labels.get(i);
					destidx = instructions.indexOf(l);
					markSubroutineWalkDFS(sub, destidx, anyvisited);
				}
			}

			// check to see if this opcode falls through to the next instruction
			// or not; if not, return.
			switch (instructions.get(index).getOpcode()) {
				case GOTO:
				case RET:
				case TABLESWITCH:
				case LOOKUPSWITCH:
				case IRETURN:
				case LRETURN:
				case FRETURN:
				case DRETURN:
				case ARETURN:
				case RETURN:
				case ATHROW:
		        /*
                 * note: this either returns from this subroutine, or a parent
                 * subroutine which invoked it
                 */
					return;
			}

			// Use tail recursion here in the form of an outer while loop to
			// avoid our stack growing needlessly:
			index++;
		}
	}

	/**
	 * Creates the new instructions, inlining each instantiation of each
	 * subroutine until the code is fully elaborated.
	 */
	private void emitCode() {
		LinkedList<Instantiation> worklist = new LinkedList<Instantiation>();
		// Create an instantiation of the "root" subroutine, which is just the
		// main routine
		worklist.add(new Instantiation(null, mainSubroutine));

		// Emit instantiations of each subroutine we encounter, including the
		// main subroutine
		InsnList newInstructions = new InsnList();
		List<TryCatchBlockNode> newTryCatchBlocks = new ArrayList<TryCatchBlockNode>();
		List<LocalVariableNode> newLocalVariables = new ArrayList<LocalVariableNode>();
		while (!worklist.isEmpty()) {
			Instantiation inst = worklist.removeFirst();
			emitSubroutine(inst, worklist, newInstructions, newTryCatchBlocks,
					newLocalVariables);
		}
		instructions = newInstructions;
		tryCatchBlocks = newTryCatchBlocks;
		localVariables = newLocalVariables;
	}

	/**
	 * Emits one instantiation of one subroutine, specified by
	 * <code>instant</code>. May add new instantiations that are invoked by this
	 * one to the <code>worklist</code> parameter, and new try/catch blocks to
	 * <code>newTryCatchBlocks</code>.
	 *
	 * @param instant           the instantiation that must be performed.
	 * @param worklist          list of the instantiations that remain to be done.
	 * @param newInstructions   the instruction list to which the instantiated code must be
	 *                          appended.
	 * @param newTryCatchBlocks the exception handler list to which the instantiated handlers
	 *                          must be appended.
	 */
	private void emitSubroutine(final Instantiation instant,
	                            final List<Instantiation> worklist, final InsnList newInstructions,
	                            final List<TryCatchBlockNode> newTryCatchBlocks,
	                            final List<LocalVariableNode> newLocalVariables) {
		LabelNode duplbl = null;

		if (LOGGING) {
			log("--------------------------------------------------------");
			log("Emitting instantiation of subroutine " + instant.subroutine);
		}

		// Emit the relevant instructions for this instantiation, translating
		// labels and jump targets as we go:
		for (int i = 0, c = instructions.size(); i < c; i++) {
			AbstractInsnNode insn = instructions.get(i);
			Instantiation owner = instant.findOwner(i);

			// Always remap labels:
			if (insn.getType() == AbstractInsnNode.LABEL) {
				// Translate labels into their renamed equivalents.
				// Avoid adding the same label more than once. Note
				// that because we own this instruction the gotoTable
				// and the rangeTable will always agree.
				LabelNode ilbl = (LabelNode) insn;
				LabelNode remap = instant.rangeLabel(ilbl);
				if (LOGGING) {
					// TODO use of default toString().
					log("Translating lbl #" + i + ':' + ilbl + " to " + remap);
				}
				if (remap != duplbl) {
					newInstructions.add(remap);
					duplbl = remap;
				}
				continue;
			}

			// We don't want to emit instructions that were already
			// emitted by a subroutine higher on the stack. Note that
			// it is still possible for a given instruction to be
			// emitted twice because it may belong to two subroutines
			// that do not invoke each other.
			if (owner != instant) {
				continue;
			}

			if (LOGGING) {
				log("Emitting inst #" + i);
			}

			if (insn.getOpcode() == RET) {
				// Translate RET instruction(s) to a jump to the return label
				// for the appropriate instantiation. The problem is that the
				// subroutine may "fall through" to the ret of a parent
				// subroutine; therefore, to find the appropriate ret label we
				// find the lowest subroutine on the stack that claims to own
				// this instruction. See the class javadoc comment for an
				// explanation on why this technique is safe (note: it is only
				// safe if the input is verifiable).
				LabelNode retlabel = null;
				for (Instantiation p = instant; p != null; p = p.previous) {
					if (p.subroutine.get(i)) {
						retlabel = p.returnLabel;
					}
				}
				if (retlabel == null) {
					// This is only possible if the mainSubroutine owns a RET
					// instruction, which should never happen for verifiable
					// code.
					throw new RuntimeException("Instruction #" + i
							+ " is a RET not owned by any subroutine");
				}
				newInstructions.add(new JumpInsnNode(GOTO, retlabel));
			} else if (insn.getOpcode() == JSR) {
				LabelNode lbl = ((JumpInsnNode) insn).label;
				BitSet sub = subroutineHeads.get(lbl);
				Instantiation newinst = new Instantiation(instant, sub);
				LabelNode startlbl = newinst.gotoLabel(lbl);

				if (LOGGING) {
					log(" Creating instantiation of subr " + sub);
				}

				// Rather than JSRing, we will jump to the inline version and
				// push NULL for what was once the return value. This hack
				// allows us to avoid doing any sort of data flow analysis to
				// figure out which instructions manipulate the old return value
				// pointer which is now known to be unneeded.
				newInstructions.add(new InsnNode(ACONST_NULL));
				newInstructions.add(new JumpInsnNode(GOTO, startlbl));
				newInstructions.add(newinst.returnLabel);

				// Insert this new instantiation into the queue to be emitted
				// later.
				worklist.add(newinst);
			} else {
				newInstructions.add(insn.clone(instant));
			}
		}

		// Emit try/catch blocks that are relevant to this method.
		for (Iterator<TryCatchBlockNode> it = tryCatchBlocks.iterator(); it
				.hasNext(); ) {
			TryCatchBlockNode trycatch = it.next();

			if (LOGGING) {
				// TODO use of default toString().
				log("try catch block original labels=" + trycatch.start + '-'
						+ trycatch.end + "->" + trycatch.handler);
			}

			final LabelNode start = instant.rangeLabel(trycatch.start);
			final LabelNode end = instant.rangeLabel(trycatch.end);

			// Ignore empty try/catch regions
			if (start == end) {
				if (LOGGING) {
					log(" try catch block empty in this subroutine");
				}
				continue;
			}

			final LabelNode handler = instant.gotoLabel(trycatch.handler);

			if (LOGGING) {
				// TODO use of default toString().
				log(" try catch block new labels=" + start + '-' + end + "->"
						+ handler);
			}

			if (start == null || end == null || handler == null) {
				throw new RuntimeException("Internal error!");
			}

			newTryCatchBlocks.add(new TryCatchBlockNode(start, end, handler,
					trycatch.type));
		}

		for (Iterator<LocalVariableNode> it = localVariables.iterator(); it
				.hasNext(); ) {
			LocalVariableNode lvnode = it.next();
			if (LOGGING) {
				log("local var " + lvnode.name);
			}
			final LabelNode start = instant.rangeLabel(lvnode.start);
			final LabelNode end = instant.rangeLabel(lvnode.end);
			if (start == end) {
				if (LOGGING) {
					log("  local variable empty in this sub");
				}
				continue;
			}
			newLocalVariables.add(new LocalVariableNode(lvnode.name,
					lvnode.desc, lvnode.signature, start, end, lvnode.index));
		}
	}

	private static void log(final String str) {
		System.err.println(str);
	}

	/**
	 * A class that represents an instantiation of a subroutine. Each
	 * instantiation has an associate "stack" --- which is a listing of those
	 * instantiations that were active when this particular instance of this
	 * subroutine was invoked. Each instantiation also has a map from the
	 * original labels of the program to the labels appropriate for this
	 * instantiation, and finally a label to return to.
	 */
	private class Instantiation extends AbstractMap<LabelNode, LabelNode> {

		/**
		 * Previous instantiations; the stack must be statically predictable to
		 * be inlinable.
		 */
		final Instantiation previous;

		/**
		 * The subroutine this is an instantiation of.
		 */
		public final BitSet subroutine;

		/**
		 * This table maps Labels from the original source to Labels pointing at
		 * code specific to this instantiation, for use in remapping try/catch
		 * blocks,as well as gotos.
		 * <p/>
		 * Note that in the presence of dual citizens instructions, that is,
		 * instructions which belong to more than one subroutine due to the
		 * merging of control flow without a RET instruction, we will map the
		 * target label of a GOTO to the label used by the instantiation lowest
		 * on the stack. This avoids code duplication during inlining in most
		 * cases.
		 *
		 * @see #findOwner(int)
		 */
		public final Map<LabelNode, LabelNode> rangeTable = new HashMap<LabelNode, LabelNode>();

		/**
		 * All returns for this instantiation will be mapped to this label
		 */
		public final LabelNode returnLabel;

		Instantiation(final Instantiation prev, final BitSet sub) {
			previous = prev;
			subroutine = sub;
			for (Instantiation p = prev; p != null; p = p.previous) {
				if (p.subroutine == sub) {
					throw new RuntimeException("Recursive invocation of " + sub);
				}
			}

			// Determine the label to return to when this subroutine terminates
			// via RET: note that the main subroutine never terminates via RET.
			if (prev != null) {
				returnLabel = new LabelNode();
			} else {
				returnLabel = null;
			}

			// Each instantiation will remap the labels from the code above to
			// refer to its particular copy of its own instructions. Note that
			// we collapse labels which point at the same instruction into one:
			// this is fairly common as we are often ignoring large chunks of
			// instructions, so what were previously distinct labels become
			// duplicates.
			LabelNode duplbl = null;
			for (int i = 0, c = instructions.size(); i < c; i++) {
				AbstractInsnNode insn = instructions.get(i);

				if (insn.getType() == AbstractInsnNode.LABEL) {
					LabelNode ilbl = (LabelNode) insn;

					if (duplbl == null) {
						// if we already have a label pointing at this spot,
						// don't recreate it.
						duplbl = new LabelNode();
					}

					// Add an entry in the rangeTable for every label
					// in the original code which points at the next
					// instruction of our own to be emitted.
					rangeTable.put(ilbl, duplbl);
				} else if (findOwner(i) == this) {
					// We will emit this instruction, so clear the 'duplbl' flag
					// since the next Label will refer to a distinct
					// instruction.
					duplbl = null;
				}
			}
		}

		/**
		 * Returns the "owner" of a particular instruction relative to this
		 * instantiation: the owner referes to the Instantiation which will emit
		 * the version of this instruction that we will execute.
		 * <p/>
		 * Typically, the return value is either <code>this</code> or
		 * <code>null</code>. <code>this</code> indicates that this
		 * instantiation will generate the version of this instruction that we
		 * will execute, and <code>null</code> indicates that this instantiation
		 * never executes the given instruction.
		 * <p/>
		 * Sometimes, however, an instruction can belong to multiple
		 * subroutines; this is called a "dual citizen" instruction (though it
		 * may belong to more than 2 subroutines), and occurs when multiple
		 * subroutines branch to common points of control. In this case, the
		 * owner is the subroutine that appears lowest on the stack, and which
		 * also owns the instruction in question.
		 *
		 * @param i the index of the instruction in the original code
		 * @return the "owner" of a particular instruction relative to this
		 *         instantiation.
		 */
		public Instantiation findOwner(final int i) {
			if (!subroutine.get(i)) {
				return null;
			}
			if (!dualCitizens.get(i)) {
				return this;
			}
			Instantiation own = this;
			for (Instantiation p = previous; p != null; p = p.previous) {
				if (p.subroutine.get(i)) {
					own = p;
				}
			}
			return own;
		}

		/**
		 * Looks up the label <code>l</code> in the <code>gotoTable</code>, thus
		 * translating it from a Label in the original code, to a Label in the
		 * inlined code that is appropriate for use by an instruction that
		 * branched to the original label.
		 *
		 * @param l The label we will be translating
		 * @return a label for use by a branch instruction in the inlined code
		 * @see #rangeLabel
		 */
		public LabelNode gotoLabel(final LabelNode l) {
			// owner should never be null, because owner is only null
			// if an instruction cannot be reached from this subroutine
			Instantiation owner = findOwner(instructions.indexOf(l));
			return owner.rangeTable.get(l);
		}

		/**
		 * Looks up the label <code>l</code> in the <code>rangeTable</code>,
		 * thus translating it from a Label in the original code, to a Label in
		 * the inlined code that is appropriate for use by an try/catch or
		 * variable use annotation.
		 *
		 * @param l The label we will be translating
		 * @return a label for use by a try/catch or variable annotation in the
		 *         original code
		 * @see #rangeTable
		 */
		public LabelNode rangeLabel(final LabelNode l) {
			return rangeTable.get(l);
		}

		// AbstractMap implementation

		@Override
		public Set<Entry<LabelNode, LabelNode>> entrySet() {
			return null;
		}

		@Override
		public LabelNode get(final Object o) {
			return gotoLabel((LabelNode) o);
		}
	}
}
